DE2541083C2 - Imaging film - Google Patents

Description

Polyester,

Polycarbonate, ABS resin,

FEP fluorocarbon polymer fluorinated ethylene propylene resin,
Polyamides,

Cellulose triacetate, styrene nitrile copolymer.

7. image recording film according to any one of the preceding claims, characterized in that the surface of the protective film (16) is provided with a release agent.

8. image recording film according to claim 7, characterized in that the release agent consists of consists of a material from the following group:

55 Octadecyl acrylate acrylic acid mixed poly-

merisat,
Vinyl stearate maleic anhydride copolymer,

Siearate chromium chloride, f> o

Silicone oil,

9. image recording film according to claim «, characterized in that a release agent Copolymer of maleic anhydride and t.5 n-octodecyl vinyl ether is used.

10. The image recording film according to any one of the preceding Claims characterized in that the protective film (16) is on an image recording layer (14) is applied, which has at least one element of the following groups:

Bismuth molybdenum, polonium, cobalt, zinc, aluminum, copper, nickel, iron, tin, vanadium, germanium and silver.

The invention relates to an image recording film for dry processing in which on a A thin image recording layer of dispersion material is applied and spread over the substrate Image recording layer is another thin layer, according to the preamble of claim 1.

Such an image recording film has already been proposed (DE-OS 22 33 827). With the film of this older proposal, the other thin layer is gum arabic; it has the task of Reduce the energy required to reach the surface tension threshold. Though this picture recording film can be processed perfectly dry and permanent images can be produced with it especially during film handling both before and after Image acquisition take special precautions to the image recording layer not to blur.

It is an object of the invention to provide the image recording film of this type to that effect improve that he is better protected.

The invention is characterized in claim 1 and further developments are given in subclaims same claimed. It has been shown that by using a polymeric synthetic resin, which is at the image recording is not substantially wettable by the dispersion material of the image recording layer, the further layer can be designed as a real protective film. All of the picture recording film and especially the As a result, the image recording layer of the same is made significantly more resistant to abrasion forces so that the image recording film is handled not only manually but also mechanically. can be processed without taking special precautions to damage the film through abrasion meet are. This also improves the archivability of the exposed film. Surprisingly succeeds in solving this task without impairing the image quality and without impairing the Exposure and development of the image; the sharpness of the contours, the high contrast and the high resolution of the dry processable film are maintained.

The polymeric synthetic resin protective film hinders the mobility of the deformable particles Dividing the image-recording layer of dispersion material and keeping it in the disperse Condition practically not. It is thin, in particular in a layer thickness between about 0.1 and 5 μm, than flexible film formed. This flexibility or flexibility and the practical Non-wettability through the dispersion material allows the dispersion material to be exposed to the light Make promptly dispersed to spatially separate individual bodies and that these these dispersed form or arrangement is retained even after the application of energy has ended, in order to generate a latent image.

The term "dispersion" is understood here to mean that an inherently thin, solid, continuous and non-particulate film of the image recording layer is broken when due to energy absorption, the internal energy of the material beyond a critical threshold value is increased. When this threshold is reached or exceeded, areas are formed in the film that For example, they become more transparent or less reflective than others Film areas, so that a visually perceptible image is created that consists of a multitude of permeable or reflective areas as well as areas of lower permeability or reflectivity.

The dispersion materials useful in practicing the invention should be a melt or Have a softening point that is low enough to cause a temporary melting or at least one To allow softening of the material under the action of an available imaging energy. the Dispersion materials should also be designed to be at or above their melting or softening point have a viscosity low enough to allow the material to flow together ^ u small Corpuscles, globules, droplets or similar structures or at least one reduction in thickness of the material sufficient to form selected permeable or reflective areas to allow. At the same time, the dispersion material should help promote the formation of beads or droplets, preferably in the molten or softened state, have a relatively high surface tension to the substrate and the protective film. In addition, the dispersion material should be J5 in the molten or softened state only poor wettability not only with respect to the synthetic resin protective film, but also with respect to it have the substrate. An excessively great wettability of the dispersion material with respect to the substrate and the protective polymeric resin film may cause insufficient dispersion and poor quality of the Figures lead. An appropriately selected dispersion material can therefore be used in conjunction with a certain combination of a substrate and the protective film synthetic resin excellent for use -45 be suitable.

Yet another desirable property of the dispersion imaging material is relative low thermal conductivity. The importance of the low thermal conductivity of the dispersion imaging material based on the fact that this leads to a reduction in the lateral heat dissipation, so that at the boundaries between dispersed and non-dispersed material areas of the continuous, film not made up of individual particles, «lateral heat transport is limited to a minimum will. Using dispersion imaging materials with low to medium thermal conductivity generated images are therefore sharper and are characterized by a higher resolution. In those Cases where a certain dispersion imaging material is in the film coated or in a depressed state does not have a high level of opacity or low reflectivity Opacity or low reflectivity due to additive. organic dyes or very fine dispersed or powdered pigments, such as carbon black o. dsl., to the surface .- or directly to the mass of the Dispersion imaging material are promoted or brought about.

Examples of dispersion imaging are materials that meet the above requirements Metals such as bismuth, antimony, aluminum, cadmium, zinc, tin, selenium, polonium, indium o. The like. As well as their Alloys and compounds. Of these, bismuth is particularly suitable. Also useful are the chalcogenid elements with the exception of oxygen and the glassy or crystallized elements containing them Crowds. Specific examples of such materials are tellurium and manifold masses, tellurium and others Chalcogenides contain, like the following masses (for which the individual parts in atomic weight percent given are) 52.5 at% partur, 2.5 at% germanium, 2.5 at% silicon and 2.5 at% arsenic; a mass of 95 at.% tellurium, and 5 at.% silicon; a mass of 90 at .-% tellurium, 5 at .-% germanium, 3 AL-% Silicon and 2 at% antimony; a mass of 85 at.% tellurium, 10 at.% germanium and 5 Al-% bismuth; one Mass of 85 at-% tellurium, 10 mass-% germanium, 2.5 at-% indium and 23 at-% GaUhim; a mass from 85 at% tellurium, 10 at% silicon, 4 at% bismuth and

1 at% thallium; a mass of 70 at .-% tellurium, 10 at-% arsenic, 10 at-% germanium and 10 at-% Antimony; a mass of 60 at% tellurium, 20 at% germanium, 10 at% selenium, and 10 at% sulfur; a mass of 60 at% tellurium, 20 at% germanium and 20 at% selenium; a mass of 60 at% tellurium. 20 at% arsenic, 10 at% germanium and 10 at% gallium; a mass of 81 at% tellurium, 15 at% Germanium, 2 at% sulfur and 2 at% indium; a mass of 90 at% selenium, 8 at% germanium and

2 at% thallium: a mass of 85 at% selenium, 10 at% germanium and 5 at% copper; a mass from 85 at-% be, 14 at-% tellurium and 1 at-% bromine; a mass of 70 at% selenium, 20 at% germanium and 10 at% bismuth; a mass of 95 at% selenium and 5 at% sulfur; and modifications of these Crowds.

3persionsabbildungsmaterialien such materials to be considered, whose melting or softening point in the range of 150 to 750 ° C, in particular from about 250 to 450 ⁰ C, is the viscosity of which at the melting or softening point or above ^this: are generally collectively referred to as excellent D in the range from approx. ³ to approx. 10 ⁴ Pa-S, their thermal conductivity in the range from 4.2 · ΙΟ- ^{4 to 4} ^ ■ 10- 'J · cm / cm ² s "C and their surface tension in the softened or molten state is is in the range of 5 x ΙΟ- ⁴ to 10 ~ ² N / cm. Some of the materials with surface tensions in the upper part of the range require for the operability möplidierweise ultrasonic vibrations. in general those are materials preferable have a low in molten form to have an average surface tension within the stated range, even if the surface tension with respect to the substrate and the protective film made of polymeric resin must be high enough; j ll that their wettability by the melted or softened dispersion imaging material! is relatively small, so that the desired particles or spheres can form when the material is dispersed by radiant energy. In other words, when the surface tension of the dispersion imaging material is low, there are usually only a small number of suitable substrates and Dolvmerer resins to choose from. if

on the other hand, the surface tension of the molten one If the dispersion imaging material has higher values, there are usually more substrates and polymeric resins available to select.

It should be noted that for the suitability of a dispersion imaging material for the purposes of Invention not a single property of a given material is crucial. Rather, it is It is only a combination of the above properties that dictates the selection of the most suitable dispersion imaging material permitted for a given system and use, and to these properties also include energy impermeability, the reflectivity, the adhesiveness to the substrate and the suitability for light weight Attachment to this, and additional factors such as a relatively low vapor pressure at the melting or softening temperature or at the temperature used during the dispersion is achieved. As indicated above, bismuth meets almost all of these criteria. Bismuth is to a large extent energy impermeable, melts at a relatively low temperature, namely at approx. 269 ° C, and leaves easily attach to plastic substrates. The generally low thermal conductivity also makes it possible of bismuth using low intensity and short duration radiant energy Disperse the imaging material in the irradiated areas with minimal transverse transport of Heat, which causes blurring of outlines so that extremely sharp images of high resolution are obtained.

The continuous, non-particulate film of the dispersion imaging material can be applied to a selected substrate in any conventional manner such as vacuum evaporation and deposition, sputtering, solution application followed by evaporation of the solvent, etc. The thickness of the film of dispersion imaging material can vary within certain limits. The object on which the invention is based, however, is achieved in particular by dispersion imaging materials in film thicknesses of about 10 to 250 nm, usually from about 50 to 200 nm and in the particularly preferred case from about 70 to 100 nm. The optical densities of a film of the thicknesses given are then in the range from about 0.7 to about 3 and usually from about 1/2 to 2. The dispersion imaging materials used in the production of the image receiving film according to the invention are also characterized by their high quality Gamma off. : which is usually greater than 10. The high definition attainable with the film as a result of the high gamma of the dispersion imaging material enables films to be made with resolution on the order of 600 lines / mm or greater. ;

The substrates useful for the purposes of the invention can be selected from a wide group. The substrate can be an inorganic material such as silica glass. Be ceramic, metal or mica. Preferred are organic substrates that can be used to form continuous lengths of substrate material in roll form. In this case, such substrates are preferred whose Wärmieitfähigkeit less than 6.3 - 10 ^"3 J · cm / cm ² s' C ι at room temperature.

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Polyesters, for which polyethylene glycol terephthalate Example is. Other suitable organic substrates are Polyamides, cellulose acetate. Polystyrene. Polyethylene, in particular cross-linked polyethylene. Polypropylene and many others. In general, all of these can be used as substrates organic materials can be used with benefit.

which can be brought into the form of a thin film or a sheet and which are opposite to the chosen dispersion imaging material have a good affinity so that the latter easily adhere to it can be attached. Also, as above, it should

ι indicated, a selected substrate in as possible to a small extent be wettable by the molten dispersion imaging material, so that the dispersion imaging material when exposed to radiant energy, to the preferred form of small spheres or similarly shaped particles is dispersible. Materials such as Mylar in film form and cellulose acetate film, both of which provide slides. Highly filled ones are also desirable Low porosity papers of various grades or other energy-impermeable cellulose products to generate images for viewing at sight. The thickness of the preferred organic substrates can be in the range of approx. 50 bc 375 μm, with a thickness of approx. 175 μπ is particularly suitable if the film is to be used for the production of microfilm or microfiche. When a certain substrate one can use in combination with a given dispersion imaging material would like, is unsatisfactory because of its wettability, there is the possibility of attaching a Intermediate layer on the substrate that enhances the wettability by a given dispersion imaging material reduced, so that the dispersion imaging material when exposed to radiant energy from the required threshold is promptly dispersed. This can be achieved, for example, in that the substrate prior to applying the dispersion imaging maize coated with a material of low wettability by the dispersion imaging material will. Examples of suitable materials are aluminum oxide, silicon oxide or the like. The thickness of a such a film can be in the range from 1 to 50 nm, usually from about 10 to 30 nm. The same The method of treating the surface of the substrate can also use the dispersion imaging material for formation enable smaller units in the dispersed phase, if the size of the units were otherwise unacceptable. With this measure it is possible the selection of suitable substrate materials for a given dispersion imaging material largely to enlarge.

The polymeric resins for use as a masking protective film for the dispersion imaging material can be selected from an extensive group of materials; belong to this group film-forming plastics such as polyurethanes: vinyl polymers and copolymers for polyvinyldene chloride. Polyvinyl acetate and polyvinyl butyral are examples; Copolymers of vinylidene chloride and Vinyl acetate; Vinylidene chloride and acrylonitrile: and vinyl chloride and vinyl acetate; Polycarbonates; Polyamides; Polyester: FEP-Fl - '. Orcarbon polymers like that Copolymer of tetrafluoroethylene and hexafluoropropylene; Cellulose triacetate: styrene-acrylonitrile copolymers: Acrylonitrile butadiene styrofoam (ABS -) -

iTiiaCnpoiyrncnsSic; G. dg !. Particularly suitable is highly elastic plastic made of practically uncrosslinked, linear polyurethane. Formed from this material

Protective films are characterized by their high strength Association with toughness at very small thicknesses. The films also have an extraordinary Resistance to abrasion and harmful atmospheric influences as well as high dimensional stability on. The copolymer is also highly suitable as a protective film for the dispersion imaging film "on vinylidene chloride and vinyl acetate. Protective films formed from this material are characterized by high dimensional stability, excellent resistance to abrasion and chemical attack as well as the .ins. their flexibility about one to maintain a wide temperature range.

The protective film made of polymeric resin is applied to the film made of dispersion material, advantageously in the form of a solution in a solvent. For example, the polyurethane product can be applied as a solution with 20% solids in methyl ethyl ketone. The application can be carried out in any known manner, including by spraying. Roller application. Nozzle application, painting or the like. The thickness of the top layer made of polymeric resin can be from about 0.1 to about 5 μm or more. Advantageously, the thickness of the synthetic resin layer / wipe cc. 0.5 and approx. 3 μτη.

The Bildaufnahmmng ^ film according to the invention without further ado to machine processing methods adjust. To prevent the protective film from jamming or sticking to machine parts such as rollers prevent or substantially reduce it, can vorf '!! iaiterwciSc around uci outer surface of the same a thin film or a layer of a release agent or an anti-sticking material is attached will. Various agents can be used for this, and specific examples are octadecyl acrylate-acrylic acid copolymers, Vinyl stearate maleic anhydride copolymers, stearate

chromchiorid, silicone oils, o. dgi. An excellent one The product for this application is a copolymer of maleic anhydride and n-octodecyl vinyl ether.

In the drawing, one embodiment of the imaging film according to the invention is at more targeted Radiant energy exposure to create an imaged product.

The illustrated embodiment of the film 10 consists of a substrate 12, for example made of Mylar, on which a thin, continuous, not composed of individual particles layer 14 made of an energy-impermeable (Opaque) dispersion material, such as bismuth, is arranged. On layer 14 off Dispersion imaging is a permeable one Protective film 16 made of a polymer resin such as polyurethane. On the protective film 16 is an imaging mask 18, for example an imaged dry overmaskc, with opaque parts or Areas I82-I83 and a permeable part or Area 180 put on. From a suitable source, like a xenon flash gun, emitted electromagnetic energy is indicated by arrows 20.

As in Fig. 1 to 4, when a short pulse of electromagnetic energy (arrows 20) above a threshold is applied, this pulse of energy is absorbed and scattered by the opaque regions ISa-ISa of the mask IS, so that the layer 14 of dispersion imaging material in the image recording film 10 in the areas below the areas 18.7 and 18.7 of the same are not reached and influenced. Such a short energy pulse, however, passes through the area is permeable \ Sb of the mask 18 and the transparent protective film 16 without hindrance to the continuous, non-structured particulate layer 14 of the dispersion material and is absorbed by it. This absorption of the pulse of electromagnetic energy has the consequence that the layer 14 is heated to at least a softened or molten state and then broken up in the region 26 of the film 10 and dispersed into small, widely spaced globules 24, whereby the Area 26 is essentially energy-permeable (translucent) (FIG. 5). This dispersion of the layer 14 in the heated, softened or melted areas 26 is in principle caused by the surface tension of the heated dispersion material, which causes the heated material to form the globules 24 which are far apart from one another. After being formed by the brief pulse of electromagnetic energy, these globules cool rapidly and retain this spherical state, so that the essentially permeable or transparent state of the area 26 (FIG. 5) is maintained.

The spaced apart spheres 24 have a dimension in the direction of thickness that is greater is called the thickness dimension of the thin continuous layer 14 because the volume of the material in the Area 26 has of course remained the same. However, this extra thickness is thanks to the elasticity and Flexibility of the substrate 12 as well as the protective resin protective film 16 of the image-taking film 10 without further recorded. Like F i g. 5 shows, the protective film 16 tends under the action of the energy pulse tend to soften and become thinner in the area of the beads and the spaces between the Partial fill in beads 24.

The finished product 30 provided with a picture (Fig. 5), which allows the retrieval of the data or messages recorded in it as an image, consists of the im essentially energy-permeable (translucent) substrate 12, the essentially permeable Protective film 16 made of resin, the continuous, massive, substantially impermeable areas 14a-14a and the substantially permeable area 26 containing the contains beads 24 formed from dispersion material. These globules 24 are so extraordinary small dimensions, for example on the order of 1 μπι or below and are located in such distances from one another that the exposed area 26 even with considerable magnification in is highly permeable. The image receiving film 10 is a positive of the mask 18. That in the film 10 The image produced is a slide that can be read through.

The dispersion material in the exposed area became more perfect in shape in the drawing Spheres shown. Depending on the type and composition of the dispersion imaging material, the conditions under which the energy was applied to the film, and the type of substrate and the Protective polymer resin film, the dispersed material can of course take the shape of flattened spheres, "Lenses". Pustules, droplets, irregularly shaped bodies, or other shapes like that of flakes, assume. In order to be useful,

The dispersed material is in such a form that the difference in permeability or reflectivity between the dispersed areas and the non-dispersed areas included in have remained in their original state, can be easily ascertained. This difference can rather than by areas formed by spheres or corpuscles of the dispersion imaging material in the manner described above are created by areas in which the thickness of the dispersion imaging material is reduced accordingly.

Any source of energy can be used provided that it is appropriate for the dispersion able to deliver the amount of energy required by short energy pulses. Particularly suitable for exposure through a mask are the devices commonly known as electronic flash guns and which short flashes, for example from approx. 10 ns up to several hundred ms duration or more and whose emiiiierie energy is sufficient liui.ii isi, to disperse the dispersion imaging material. Other energy sources and forms, for example flashlight lamps, infrared lamps, particle beam generators or the like can also be used can be used provided that they are effective for melting or softening the dispersion imaging material and capable of supplying the heat or other energy required to disperse the same. A suitable energy source with sufficient energy density is the laser. Using a laser for example in combination with a dispersion imaging material such as bismuth it is possible, for example to use cheaper lasers for imaging with laser beam scanning and modulation. To the However, full format flash exposures through a mask are the flash guns mentioned above or similar devices with high light and heat output opposite the imaging mask and preferable to an energy beam held at rest to the image pickup film.

When choosing the intensity and duration of the energy exposure for exposure by a Some care must be exercised through the image mask. Because also through the impermeable areas of the If some energy passes through the image mask, make sure that the intensity and duration of the energy impact are dimensioned in such a way that through the "transparent" or energy-permeable areas of the imaging mask sufficient energy passes to disperse the dispersion imaging material into the to cause relevant areas of the film, the amount of energy brought into effect, however, small enough that in those areas of the film of dispersion imaging material which are the "opaque" Corresponding to areas or energy-impermeable areas of the imaging mask, preferably none Dispersion takes place

The images produced with the image receiving film according to the invention can be directly or with the aid of suitable sight or look-through reading or viewing devices viewed or read. The images can also be read with the help of test equipment whose operation is based on optical, electrical or other physical principles.

The invention is explained in more detail below with the aid of a few examples.

Example I.

On a polyester film of 125 μη \ thickness, a bismuth film of 80 nm by sputtering is

n, thickness applied. A 1 μm is applied to the bismuth film thick, transparent protection / film made from a copolymer from vinylidene chloride and vinyl acetate by spraying a solution of the copolymer with 25% solids in methyl ethyl ketone and dry

, .-, 80 ° C applied.

A chrome mask containing a micro-recording is placed on top of the protective film. ur.J the film is passed through the mask with a 0.5 ms flash from an electron flash / unit of ho-

jι> iicyvvcil 700 im Αυ5ίϋΓινι VOPi 1 ~ j ΓΠΓΓί VGH dc "Ebc ^ C dcü Filmes exposed.

A slide of the micro-recording is obtained with excellent resolution and high definition. The resin cover layer exhibits excellent resistance to abrasion in handling.

Example Il

On a polystyrene film of 125 μm thickness is a Bismuth film of 100 nm thickness evaporated in vacuo.

- ,, An energy-permeable protective film of polyurethane with a thickness of 1 μm is formed on the bismuth film by spraying on a solution of polyurethane with 20% solids in methyl ethyl ketone and drying at 80 ⁵ C. A

j- A dry silver mask with a micrograph is applied and the imaging film is exposed through the mask to a 10 ms flash from a clear flash lamp at a distance of 12.5 mm.
A slide of the micrograph with high resolution and high contour definition is obtained.

Example III

On a 125 μm thick polyester film is through A 120 nm thick film of tellurium is applied by vapor deposition in vacuo. On the tellurium film, as according to Example II. An energy-permeable protective film made of polyurethane applied. On the polyurethane is a a thin film of a release agent or an anti-sticking material is applied.

A microfilm original is used as a mask made from a silver halide emulsion on a cellulose acetate substrate placed on the protective film with a representation of writing. The ray is on the image plane a pulsed argon laser of 100 mW, focused, and the original is used to create a copy the same on the tellurium layer with the pulsating laser with a pulse width of 4 μ5 line by line scanned.

A slide is obtained with a high resolution and sharpness of the contours of the one shown on the original font

1 sheet of drawings

Claims (6)

1 claims: 1. An image recording film for dry processing in which a thin film is placed on a substrate Image recording layer of dispersion material is applied to the points of exposure of energy, especially electromagnetic radiation. its above a threshold Surface tension changes and from the essentially homogeneous state of a contiguous Film in the substantially dispersed state of spaced apart Corpuscles and in which there is another thin one over the image recording layer Layer is located, which is the energy for image recording Drawing layer lets through, characterized in that that the further layer is designed as a protective film (16) and made of such a polymer There is synthetic resin, which is not substantially wettable by the dispersion material when the image is recorded is 2. 'Image recording film according to claim i, characterized in that the protective film (16) is a Has layer thickness between about 0.1 and 5 μm. 3. Image recording film according to claim 1 or 2, characterized in that the protective film (16) consists of Polyurethane is made. 4. image recording film according to claim 1 or 2, characterized in that the protective film (16) consists of a copolymer of vinyl or vinyl mixed polymers. 5. BildauL.eichnungsfilm according to claim 4, characterized characterized in that you protective film (16) from Consists of vinylidene chloride and vinyl acetate. 6. image recording film according to claim 1 or 2, characterized in that the protective film (16) consists of a material from the following group: